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Stabilization of chaotic and non-permanent food-web dynamics

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Abstract.

Several decades of dynamical analyses of food-web networks [1-6] have led to important insights into the effects of complexity, omnivory and interaction strength on food-web stability [6-8]. Several recent insights [7, 8] are based on nonlinear bioenergetic consumer-resource models [9] that display chaotic behavior in three species food chains [10, 11] which can be stabilized by omnivory [7] and weak interaction of a fourth species [8]. We slightly relax feeding on low-density prey in these models by modifying standard food-web interactions known as “type II” functional responses [12]. This change drastically alters the dynamics of realistic systems containing up to ten species. Our modification stabilizes chaotic dynamics in three species systems and reduces or eliminates extinctions and non-persistent chaos [11] in ten species systems. This increased stability allows analysis of systems with greater biodiversity than in earlier work and suggests that dynamic stability is not as severe a constraint on the structure of large food webs as previously thought. The sensitivity of dynamical models to small changes in the predator-prey functional response well within the range of what is empirically observed suggests that functional response is a crucial aspect of species interactions that must be more precisely addressed in empirical studies.

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Authors and Affiliations

  1. Pacific Ecoinformatics and Computational Ecology Lab, Rocky Mountain Biological Laboratory, PO Box 519, CO 81224, Crested Butte, USA

    R. J. Williams & N. D. Martinez

Authors
  1. R. J. Williams
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  2. N. D. Martinez
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Correspondence to N. D. Martinez.

Additional information

Received: 7 December 2003, Published online: 14 May 2004

PACS:

05.45.-a Nonlinear dynamics and nonlinear dynamical systems - 05.45.Jn High-dimensional chaos - 05.45.Pq Numerical simulations of chaotic systems - 87.23.-n Ecology and evolution

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Williams, R.J., Martinez, N.D. Stabilization of chaotic and non-permanent food-web dynamics. Eur. Phys. J. B 38, 297–303 (2004). https://doi.org/10.1140/epjb/e2004-00122-1

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